System and method for powering on after verifying proper operation of a charge pump and voltage regulator

ABSTRACT

Embodiments of methods, apparatuses, devices and systems associated with a power management system are disclosed. In one such embodiment, a power management system includes a state machine, capable of transitioning the power management system to a safe state when an input signal and/or an output signal from a component of the power management system indicates occurrence of an error in the component.

BACKGROUND

Electrical and/or electronic circuits operate using a power source. Somepower sources provide direct current (DC) electricity in the form of DCcurrent and/or DC voltage. An associated issue with such electricaland/or electronic circuits may be lower power operation modes and/orwell-defined power initiation sequences. Low power operation modes mayassist manufacturers in complying with regulations designed to result inlower power consumption. Such regulations continue to lower the powerconsumption standards for electronics, computer equipment, computers,monitors and/or peripherals, such as printers, appliances, and the like.Meeting these regulations can cause difficulty with attaining designobjectives, such as cost, complexity, and size.

BRIEF DESCRIPTION OF THE DRAWINGS

Subject matter is particularly pointed out and distinctly claimed in theconcluding portion of the specification. The claimed subject matter,however, both as to organization and method of operation, together withobjects, features, and advantages thereof, may best be understood byreference of the following detailed description when read with theaccompanying drawings in which:

FIG. 1 is a schematic diagram illustrating one embodiment of anintegrated circuit;

FIG. 2 is a flow chart illustrating an embodiment of a power managementsystem state machine;

FIG. 3 is a schematic diagram illustrating an embodiment of a chargepump;

FIG. 4 is a schematic diagram illustrating an embodiment of a DC-DCvoltage regulator;

FIG. 5 is a schematic diagram illustrating another embodiment of a DC-DCvoltage regulator;

FIG. 6 is a schematic diagram illustrating an embodiment of an H-bridgeand DC motor;

FIG. 7 is a schematic diagram illustrating an embodiment of a systemthat includes an embodiment of a power-consuming device, such as acomputer peripheral.

DETAILED DESCRIPTION

In the following detailed description, numerous specific details are setforth to provide a thorough understanding of the claimed subject matter.However, it will be understood by those skilled in the art that theclaimed subject matter may be practiced without these specific details.In other instances, methods, procedures, components and/or circuits thatwould be understood by one of ordinary skill have not been described indetail so as not to obscure the described embodiments of claimed subjectmatter.

Reference throughout this specification to “one embodiment” and/or “anembodiment” means that a particular feature, structure, and/orcharacteristic described may be included in at least one embodiment.Thus, the appearance of the phrases “in one embodiment” or “in anembodiment” in various places throughout this specification typically donot refer to one particular embodiment or the same embodiment.Furthermore, various features, structures, and/or characteristicsdescribed through out this specification may be combined in any suitablemanner in one or more embodiments.

FIG. 1 is a schematic diagram illustrating an embodiment 100 of a powermanagement system of an integrated circuit (IC), although claimedsubject matter is not limited in scope to this particular embodiment.For example, alternative embodiments may or may not be embodied in or onone or even more than one IC. This particular embodiment, however,includes an IC that incorporates switching power devices, such as, forthis embodiment, switching motor drive circuits, such as 110, 115 and120, and switching voltage regulators, such as 125, 130 and 135.Embodiment 100 also includes a charge pump 145 and a clock oscillator140. Embodiment 100 may further include a startup controller 150, astate machine, such as a power management system state machine 155, anda supervisor circuit 160. The state machine may be implemented in avariety of ways including but not limited to an application specificintegrated circuit, a component of an application specific integratedcircuit, and/or a computing device executing instructions that may bestored in any variety of storage media, to name but a few examples. Itshould be noted that claimed subject matter is not limited to specificimplementations of the state machine. In this context, a switching powerdevice refers to a circuit or component of a circuit that regulatesand/or modulates power wherein an aspect of that regulation and/ormodulation relates to signals that switch or change between distinctelectrical levels, such as current levels and/or voltage levels, forexample.

Although claimed subject matter is not limited in scope in this respect,embodiment 100 includes voltage regulators that comprise DC-DC voltageregulators. In this embodiment, for example, 32 volts DC (not shown) isto be applied to embodiment 100 , whereas switching voltage regulator125 comprises a 3.3 volt switching regulator. Likewise, in thisparticular embodiment, auxiliary regulators 130 and 135 also compriseDC-DC voltage regulators, although other regulators may alternatively beemployed, such as AC-DC or AC-AC regulators, for example, depending onthe particular application involved. In this embodiment, regulators 130and 135 may be employed to produce a higher or lower output voltagelevel other than 3.3 volts DC, if desired. It is noted, therefore, thatthese voltage values are merely examples and are not intended in any wayto limit the scope of claimed subject matter. Thus, switching voltageregulators may provide any desired voltage level or a plurality ofvoltage levels. Likewise, a host of potential architectures areavailable for switching regulators, including, without limitation, buckconverters, regulators that employ feedback, push-pull voltageregulators, and the like.

Although claimed subject matter is not limited in scope in this respect,startup controller 150 may comprise a circuit or circuit component thatmay regulate a startup sequence for embodiment 100. Startup controller150 may comprise a separate circuit or may be included as component of alarger circuit as shown in embodiment 100, for example. It is notedhowever that claimed subject matter is not limited to a particularembodiment of startup controller 150. Likewise, alternative embodimentsmay or may not be embodied in or on one or even more than one IC.

Embodiment 100 may be initiated by an external event, e.g., an eventthat may be initiated outside of embodiment 100, such as a user pressingan “on” button on an apparatus in which embodiment 100 is employed, forexample, although of course claimed subject matter is not limited inscope in that respect. In this context an external event may be anyevent that originates outside of embodiment 100, such as, but in no waylimited to the examples provided above and below, for example.Initiating embodiment 100 may result in a system supply voltage, such as32 volts DC for example, and an initiation supply voltage, such as ananalog biasing voltage, to be applied to startup controller 150. At atime in which the system supply voltage and the initiation supplyvoltage both exceed an activation threshold, such as an under-voltagelockout (UVLO) threshold, startup controller 150 may generate an outputsignal that may be supplied to charge pump 145. Charge pump 145 maytherefore be initiated by the output signal of startup controller 150 inthis embodiment. Charge pump 145 may then generate an output signal, orsignals, to be applied to one and/or more of voltage regulators 125,130, and 135, for example, though claimed subject matter is not limitedin this respect.

Supervisor circuit 160 may monitor input signals, input ports, outputsignals and/or output ports of the above described circuit components,such as switching voltage regulators 125, 130 and 135, charge pump 145,and switching motor drive circuits 110, 115 and 120, for example. If noerrors are indicated in the input signals and/or output signals of anyof the above circuits supervisor circuit 160 may move embodiment 100into a full power mode in which all circuit components are provided withsufficient voltage to function as desired, depending for example on acircuit environment for embodiment 100. In this context, the term errorrefers to any one or any combination of the input signals and/or outputsignals of the circuits of an embodiment or any components thereof beingoutside a desired range. Embodiment 100 may be employed as part of aprinter, a computer, a home appliance, a digital camera, such as adigital still or a digital video camera, a cell phone, a personaldigital assistant, a television, a radio, a DVD player, a CD player, acassette player, a hard drive, a DVD burner, a CD burner, a floppydrive, an electronic game device, etc. In some applications, of course,alternate startup sequences may be employed. It is noted, therefore,that the startup sequence discussed above is merely an example and isnot intended in any way to limit the scope of claimed subject matter.Though depicted as a separate circuit component above, that is merely anexample of the supervisor circuit and supervisor circuit logic and in noway is intended to limit claimed subject matter.

FIG. 2 is a flowchart illustrating an embodiment of one possible startupsequence for embodiment 100. Furthermore, the flowchart is not intendedin any way to limit the scope of claimed subject matter. With referenceto FIG. 2, embodiment 100 begins in a Power Off State 200. An externalevent, such as a user activating a device associated with embodiment100, for example, may typically apply one and/or more voltages tostartup controller 150, such as those described above with respect toFIG. 1, for example. If the one and/or more voltages achieve arespective threshold value, power management system state machine 155may transition embodiment 100 into a startup state 210. In startup state210, startup controller 150 may generate an output signal, such as anoutput voltage (not shown), for example. The output signal from startupcontroller 150 may then be applied to charge pump 145. If the outputsignal from startup controller 150 reaches a respective threshold value,power management system state machine 155 may advance embodiment 100into a start charge pump state 220 in which charge pump 145 may beinitiated. As discussed more fully below, charge pump 145 may generate acharge pump output signal (not shown), such as an output voltage, forexample. If the charge pump output voltage meets and/or exceeds a chargepump threshold value, power management system state machine 155 mayadvance embodiment 100 into a start system regulators state 230 whereinvoltage regulators 125, 130, and/or 135 may be initiated. If powermanagement state machine 155 does not detect any errors from the inputsignals and/or output signals of the voltage regulators 125, 130, and/or135, power management state machine 155 may advance embodiment 100 to apower on state 240, wherein all or substantially all components and/orcircuit components, such as motor drives 110, 115, and 120, for example,of embodiment 100 may be initiated and proceed to a full power operationmode.

Referring to FIG. 2, embodiment 100 may also operate in a sleep modewherein embodiment 100 may enter into a sleep mode state 250. In sleepmode state 250, some but not all or substantially all of the componentsand/or circuit components of embodiment 100 may remain in an “on” state.For example, in sleep mode state 250, startup controller 150, powermanagement system state machine 155, and supervisor circuit 160 may bemaintained in a full power state while other components and/or circuitcomponents are powered off. In this way, internal events, such as in thecase of an all-in-one printer, an incoming fax, copy and/or printrequest for example, may provide a sufficient voltage to startupcontroller 150 such that startup controller 150 may initiate the startupsequence, such as that described above, and return embodiment 100 to thepower on state. In this context, an internal event may comprise anyevent originating within embodiment 100, though claimed subject matteris not limited in this regard, for example. In addition, while in sleepmode state 250, an external event, such as a user pressing a button, forexample, may likewise provide a sufficient voltage to startup controller150 such that startup controller 150 may initiate the startup sequencedescribed above and return embodiment 100 to the power on state, asdescribed more fully above. Embodiment 100 may be placed in sleep modein a variety of ways, including but in no way limited to, an internaltimer and/or a user generated event, such as a button push, for example,either of which may generate a signal to power management system statemachine 155 to transition the state of embodiment 100 from power onstate 240 to sleep mode state 250. Of course, claimed subject matter isnot limited to these examples.

Embodiment 100 may return to power off state 200 from power on state 240in response to an external signal and/or external event, such as a userpushing a button and/or a signal generated by a timer that is triggeredafter a specified idle time, for example. Such events may prompt powermanagement system state machine 155 to transition embodiment 100 intopower off state 200. As part of the process, power management systemstate machine 155 may place embodiment 100 into a power off delay mode260. Delay mode 260 may provide a delay, such as a 3-millisecond delay,for example, though other delay periods may also be used, depending upona variety of factors, including but not limited to the particularapparatus, which may allow associated software systems time to power offassociated external circuits, such as motor control integrated circuits(not shown), for example, prior to embodiment 100 entering the power offstate. The particular delay period and/or a having delay period ingeneral are mentioned for illustrative purposes and are not intended inany way to limit the scope of claimed subject matter.

Supervisor circuit 160 may include supervisor circuit logic (not shown).In embodiment 100, supervisor circuit 160 monitors any and/or all of thefollowing parameters for the above mentioned components of embodiment100: a system supply voltage, 32 volts, for example; an analog biasvoltage; temperature sensor circuits (not shown); and timer circuits(not shown). If any one of the above parameters deviates from a definedrange of acceptable values, for this particular embodiment, supervisorcircuit 160 may generate an appropriate reset signal which may result inpower management system state machine 155 transitioning embodiment 100into one of a set of safe states, as described more fully below. In thiscontext, the term safe states refers to states of the embodiment inwhich the embodiment, such as a circuit embodiment, for example, may beplaced if one or more errors occur so that the error and/or errorsresult in no harm or a limited amount of harm to the particularembodiment. Of course, the particular monitored parameters discussedabove are merely examples and are in no way intended to limit the scopeof claimed subject matter.

The following is merely an example of the operation of an embodiment ofpower management system state machine 155 and an embodiment ofsupervisor circuit 160 and is in no way intended to limit the scope ofclaimed subject matter. By way of example, assume that embodiment 100 isin the power on state, as described above. If voltage regulator 125, forexample, a 3.3 volt regulator, encounters an error, such as a groundfault, then the output value of voltage regulator 125 may fall below anassociated under-voltage threshold. Supervisor circuit 160 which may bemonitoring many and/or all of the above described components, such asregulator 125, may therefore detect the fault due to the under-voltagecondition. Supervisor logic may then generate a reset signal associatedwith a failure of voltage regulator 125. In response to the generatedreset signal, power management system state machine 155 may transitionembodiment 100 into start system regulators state 230, which in the caseof an error in voltage regulator 125 is a safe state for thisembodiment. In system regulators state 230, embodiment 100 may attemptto again initiate voltage regulator 125. If voltage regulator 125 nowproduces a proper output voltage, then power management system statemachine 155 may advance embodiment 100 into power on state 240, aspreviously described. If, however, voltage regulator 125 continues tooutput a voltage that is outside of the acceptable range, then powermanagement system state machine 155 will not advance to power on state240, and will, instead, continue to attempt to re-initiate voltageregulator 125. In this way, embodiment 100 typically will not remain ina state in which an error is occurring. Power management system statemachine 155 and supervisor circuit 160 will, instead, transitionembodiment 100 into a safe state, as illustrated by previous examples,for example. Of course, the particular states and/or errors discussedabove are merely examples and are in no way intended to limit the scopeof claimed subject matter.

As previously described, embodiment 100 may also include a charge pump,although, again, claimed subject matter is not limit in scope toincluding a charge pump. FIG. 3 illustrates one potential embodiment ofa charge pump. Here, the charge pump is employed to provide a voltagesource greater than 32 V to assist in turning on negative-channelmetal-oxide semiconductor (NMOS) devices that may be located elsewhereon embodiment 100. This is, of course, just one possible application ofa charge pump and claimed subject matter is not limited in scope to thisparticular application. However, as illustrated in FIG. 3, thisembodiment operates by switching transistors, or here, field effecttransistors (FETs), 310 and 320 so that charge is first accumulated oncapacitor 330 followed by dumping that charge from capacitor 330 tocapacitor 340. Thus, FET 320 is turned on first, in this embodiment.Current flows from voltage source V32 through diode 350 throughcapacitor 330 and through FET 320. Thus, capacitor 330 is charged to 32volts. After capacitor 330 is charged, FET 320 switches off and FET 310switches on. Current then flows from voltage source V32 through FET 310through capacitor 330 and through diode 360 into capacitor 340. Thus,capacitor 340 is charged to above 32 volts. Comparator 370 and internalvoltage source 380 are used to determine how far above 32 volts tocharge capacitor 340. Again, this is merely one example embodiment andclaimed subject matter is not limited in scope to one example.

An embodiment of a switching voltage regulator configuration isillustrated in FIG. 4, although, of course, this is also simply oneexample. In the embodiment shown in FIG. 4, one FET is employed. Thisembodiment includes a high-side FET, 400, and a low-side diode, 410,although a variety of other embodiments may alternatively be employed.For example, 410 might instead comprise another FET. Here, 400 maycomprise a N-channel FET, for example, though a P-channel FET may beused in some designs as well, and of course claimed subject matter isnot limited in this regard. As illustrated, FET 400 provides a signalpath to inductor 420. Although not illustrated in detail, the filteredvoltage output signal is provided by inductor 420 and capacitance 430 tofeedback control circuitry 405 in FIG. 4. This particular feedbackcontrol circuitry provides a feedback signal to FET driver 415. Thus,based at least in part on the output voltage signal level, the feedbackcontrol circuitry operates to adjust the output voltage signal levelproduced by driving the input port of the FET. Of course, the feedbacksignal could be directly coupled to the FET alternatively. Here,however, in this embodiment, capacitor 435 is interposed to filter outDC bias from the signal applied to the FET. As previously discussed,this is merely one potential embodiment out of a myriad of potentialcircuits that may be employed.

Embodiment 100 may include two auxiliary voltage regulators, 130 and135. The output voltage of these switching voltage regulators may be setbased, at least in part, upon the application of an external signal. Forthis embodiment, although, of course, claimed subject matter is notlimited in scope in this respect, these regulators may be set to avoltage level from 1 volt to 16 volts. This may be implemented any oneof a number of ways and claimed subject matter is not limited to aparticular approach; however, FIG. 5 illustrates one potentialtechnique. Thus, for the embodiment shown in FIG. 5, the feedback signalis applied to a comparator 510 and compared with a reference signal,such as voltage regulator signal A, for example. Adjusting R, which mayin this context be an externally provided resistance, adjusts thereference signal, which adjusts the output voltage signal, for example.Likewise, as previously described, any one of a number of switchingvoltage regulators may be employed for 130 and 135 and claimed subjectmatter is not limited in scope to a particular type of switching voltageregulator.

As suggested above, in addition to switching power regulators,embodiment 100 may include switching power motor drive circuits orcircuitry, such as 110, 115 and 120. These circuits may provide powersignals to drive a motor external to embodiment 100. Although claimedsubject matter is not limited in scope in this respect, these motordrive circuits may include an H-bridge circuit. In this context, anH-bridge circuit refers to a circuit having an H configuration, as shownin FIG. 6, for example, in which the switching elements of the circuitmay apply current to a DC motor that adjusts the duty cycle of the motorby adjusting the duty cycle of the applied voltage.

Referring to FIG. 6, a DC motor 650 may be electrically coupled in theform of an H-bridge circuit that includes four switching elements, 610,620, 630 and 640, here FETs. Control signal circuitry 660 appliesvoltage signals to the gates of the FETs to switch the states of theswitching elements. These elements may be employed to control or adjustthe rotation speed of the DC motor, by adjusting the duty cycle of apulse voltage applied to the motor, and to reverse the direction ofrotation by changing the polarity of the applied voltage. Switchingelements 610 and 620 are coupled to a power supply V, while elements 630and 640 are coupled to ground. The motor has one terminal coupled to thejunction between 610 and 630 and the other coupled to the junctionbetween 620 and 640. By combining the switching operation of 610-640,bi-directional speed control may be realized by adjusting the voltageapplied to the DC motor. For example, when elements 620 and 630 are onand elements 610 and 640 are off, current flows from the power source toground via 620 and 630. This results in the motor rotating in a forwarddirection. Likewise, if 610 and 640 are on while 620 and 630 are off,this results in reverse current flow and, consequently, the motorrotating in an opposite direction.

FIG. 7 illustrates an embodiment 700 of a system that may include an IC710 including a switching voltage regulator and/or a switching motordrive circuit, as previously described, for example, coupled to a powerconsuming device 720, such as a computer peripheral, for example.Although claimed subject matter is not limited in scope in this respect,motors, for example, may be employed in any one of a number of potentialexternal devices, including, for example, a computer peripheral device,such as a printer, scanner, copier, a facsimile machine and/or anycombination thereof, for example. Other devices may include digitalcameras, such as digital still or digital video cameras, cell phones,personal digital assistants, televisions, radios, DVD players, CDplayers, cassette players, hard drives, DVD burners, CD burners, floppydrives, electronic game devices, etc.

As previously described, FIG. 1 and the previously described circuitryare merely example embodiments and claimed subject matter is not limitedin scope in any way to employing the previously described circuitry.Thus, other circuitry may be employed instead of or in addition to thatpreviously described. Thus, claimed subject matter is not limited inscope to the particular type of switching power devices illustrated inFIG. 1. For example, other types of switching power devices includecircuits to drive compressors, such as for a refrigerator or airconditioner, circuits to drive lighting, such as lamps or other lightingapparatuses, circuits to drive displays, circuits to drive appliances,such as blenders, toasters, mixers, and the like, circuits to driveelectronic toys, circuits to drive televisions, stereos, DVD players andCD players, and/or any other type of switching power driver circuit nowin existence and/or developed later. Thus, any device that consumespower including a switching driver or regulator circuit is includedwithin the scope of claimed subject matter.

It will, of course, also be understood that, although particularembodiments have just been described, claimed subject matter is notlimited in scope to a particular embodiment or implementation. Forexample, one embodiment may be in hardware, such as implemented on adevice or combination of devices, as previously described, for example.Likewise, although claimed subject matter is not limited in scope inthis respect, one embodiment may comprise one or more articles, such asa storage medium or storage media. This storage media, such as, one ormore CD-ROMs and/or disks, for example, may have stored thereoninstructions, that when executed by a system, such as a computer system,computing platform, or other system, for example, may result in anembodiment of a method in accordance with claimed subject matter beingexecuted, such as one of the embodiments previously described, forexample. As one potential example, a computing platform may include oneor more processing units or processors, one or more input/outputdevices, such as a display, a keyboard and/or a mouse, and/or one ormore memories, such as static random access memory, dynamic randomaccess memory, flash memory, and/or a hard drive, although, again,claimed subject matter is not limited in scope to this example.

In the preceding description, various aspects of the claimed subjectmatter have been described. For purposes of explanation, specificnumbers, systems and/or configurations were set forth to provide athorough understanding of the claimed subject matter. However, it shouldbe apparent to one skilled in the art having the benefit of thisdisclosure that the claimed subject matter may be practiced without thespecific details. In other instances, features that would be understoodby one of ordinary skill were omitted and/or simplified so as not toobscure claimed subject matter. While certain features have beenillustrated and/or described herein, many modifications, substitutions,changes and/or equivalents will now occur to those skilled in the art.It is, therefore, to be understood that the appended claims are intendedto cover all such modifications and/or changes as fall within the truespirit of claimed subject matter.

1. A power management system comprising: a state machine, capable oftransitioning the power management system to a safe state when an inputsignal and/or an output signal from a component of the power managementsystem indicates occurrence of an error in the components, wherein thestate machine is operable to transition the power management system intoa start charge pump state wherein an activation voltage is applied to acharge pump associated with the power managements system when no errorsare detected during a startup state, transition the power managementsystem into a start system regulators state wherein a voltage regulatorassociated with the power management system is initiated when no errorsare detected during the start charge pump state, and transition thepower management system into a power on state wherein an activationvoltage is applied to the component of the power management system whenno errors are detected during the start system regulators state.
 2. Thepower management system of claim 1, wherein the power management systemis adapted to provide a delay in response to the state machine enteringa start state, such that an event provided to a system startup circuithas sufficient time to reach a threshold value before the state machineadvances the power management system to a subsequent state.
 3. The powermanagement system of claim 1 wherein the state machine is adapted toprovide a delay in transitioning the power management system into apower off state from a power on state such that at least one externalcircuit may be set to an off state prior to the state machinetransitioning the power management system into the power off state. 4.The power management system of claim 3 wherein said delay is such that aplurality of external circuits may be set to an off state prior to thestate machine transitioning the power management system into the poweroff state.
 5. The power management system of claim 1, and furthercomprising a set of state conditions, each corresponding to one of a setof defined input signals and/or defined output signals of a plurality ofcomponents of the power management system.
 6. The power managementsystem of claim 1, wherein, in response to a user generated event, thestate machine is operable to transition the power management system intoa system startup state wherein an activation voltage is applied to astartup controller of the power management system.
 7. The powermanagement system of claim 5, wherein activation voltages are applied tothe plurality of components of the power management system when noerrors are detected during the start system regulators state.
 8. Thepower management system of claim 5, wherein the state machine isoperable to transition the power management system into a sleep modestate wherein the plurality of components of the power management systemare transitioned to a low power state, and wherein the state machine isoperable to return the power management system to the power on state inresponse to an internal and/or external event.
 9. The power managementsystem of claim 5, wherein the state machine is operable to transitionthe power management system into a power off state wherein the pluralityof components, the charge pump, and the voltage regulator of the powermanagement system are transitioned into a power off state.
 10. The powermanagement system of claim 5, wherein the plurality of componentscomprises at least one motor drive circuit and/or at least onecommunication circuit.
 11. The power management system of claim 1,wherein the state machine is operable to transition the power managementsystem into the power on state in response to an internal and/orexternal event.
 12. The power management system of claim 11, wherein theexternal event comprises a user generated event.
 13. A method of powermanagement for a component, comprising: enabling a charge pump if anoutput signal supplied to the charge pump from a start-up controller forthe component exceeds a first voltage signal level; after enabling thecharge pump, generating an output voltage with the charge pump; enablinga voltage regulator if the output voltage of the charge pump exceeds asecond voltage signal level; monitoring input signals and output signalsof the voltage regulator for errors during the enabling of the voltageregulator; and if no error has occurred during the enabling of thevoltage regulator, entering a power on state for the component.
 14. Themethod of claim 13, and further comprising monitoring input signals andoutput signals of said charge pump, said controller and said voltageregulator.
 15. The method of claim 14, and further comprisingtransitioning from said power on state to a safe state if a monitoredinput signal and/or output signal is outside of a desired input signalrange and/or output signal range.
 16. The method of claim 15, andfurther comprising transitioning from said safe state to said power onstate if said monitored input signal and/or output signal is within saiddesired input signal range and/or output signal range.
 17. The method ofclaim 13, and further comprising transitioning from said power on stateto a low power state in response to a first event.
 18. The method ofclaim 17, and further comprising transitioning from said low power stateto said power on state in response to a second event.
 19. The method ofclaim 17, wherein said first event comprises an internal event and/or anexternal event.
 20. The method of claim 18, wherein said second eventcomprises an internal event and/or an external event.
 21. An articlecomprising: a storage media having stored thereon instructions that whenexecuted result in power management for a component comprising: enablinga charge pump if an output signal supplied to the, charge pump from astart-up controller for the component exceeds a first voltage signallevel; after enabling the charge pump, generating an output voltage withthe charge pump; enabling a voltage regulator if the output voltage ofthe charge pump exceeds a second voltage signal level; monitoring inputsignals and output signals of the voltage regulator for errors duringthe enabling of the voltage regulator; and if no error has occurredduring the enabling of the voltage regulator, entering a power on statefor the component.
 22. The article of claim 21, wherein saidinstructions when executed further result in monitoring input signalsand output signals of said charge pump, said controller and said voltageregulator.
 23. The article of claim 22, wherein said instructions whenexecuted further result in transitioning from said power on state to asafe state if a monitored input signal and/or output signal is outsideof a desired input signal range and/or output signal range.
 24. Thearticle of claim 23, wherein said instructions when executed furtherresult in transitioning from said safe state to said power on state ifsaid monitored input signal and/or output signal is within said desiredinput signal range and/or output signal range.
 25. The article of claim21, wherein said instructions when executed further result intransitioning from said power on state to a low power state in responseto a first event.
 26. The article of claim 25, wherein said instructionswhen executed further result in transitioning from said low power stateto said power on state in response to a second event.
 27. The article ofclaim 25, wherein said first event comprises an internal event and/or anexternal event.
 28. The article of claim 26, wherein said second eventcomprises an internal event and/or an external event.